DESIGN OF PASED ARRAY OF -PLANE SECTORAL ORNS WIT LOW V.S.W.R AND IG GAIN Chandana Viswanadham 1, Prof. Prudhvi Mallikarjuna Rao 2 1 Senior Member, IEEE Abstract Modern electronic systems like Radars, jaers, satellite transponders, trackers, etc., were designed with phased array antennas in their transmitter and or receiver sections, to provide electronically steered beam with very high gain in the required direction. Linear array of horns was one of the antennas used for high power radiation applications like jaing. In these applications the antenna should operate with high powers in wide frequency ranges like 6-18 Gz. Therefore, the antenna should have low V.S.W.R over these operating frequency ranges, to protect costly high power amplifier. Further, the jaing was effective only when high power noise signal is transmitted towards the victim radar. In this paper, a 6-18 Gz band high power linear array of -plane sectoral horns with V.S.W.R less than 2.5:1 and gain more than 15.8 dbi is designed, simulated, manufactured and tested. It is observed that the simulated and measured results are in agreement. Indexed Terms: Band Width Ratio (BWR), Electronic Warfare, Impedance, Matching networks, Traveling Wave Tubes (T.W.T), Ultra Wide Band (U.W.B) I. INTRODUCTION Modern Electronic Counter Measures (E.C.M) systems are configured with high power transmitters consisting of Digital Radio Frequency Memory (D.R.F.M), high power microwave amplifiers and highly directive and electronically steerable antenna [1-2]. The antenna should withstand high power signals and shall have good matching with free space impedance (Z0) of 120π Ω. The active V.S.W.R of the array is very critical parameter in these applications and depends on V.S.W.R of each element in the array. Many engineers have experimented standard and modified techniques to improve V.S.W.R of pyramidal horns, such as dielectric loading, stub matching, etc., [3 5]. These authors also explained the disadvantages of these methods like reduction in gain and operating bandwidths, though low V.S.W.R is improved to great extent. In this paper, the details of design, simulation and measurements of 6-18 Gz linear array of -plane sectoral horns with Tuning post loading on aperture is presented to improve the V.S.W.R and gain. The simulated and measured results are in agreement. II. DESIGN EQUATIONS 2.1 Design equations The geometry of -plane sectoral horn antenna is shown at Fig. 1 [3-4] along with design parameters. 21 Feb 2017. This work is supported by D&E department, Bharat Electronics Limited, yderabad, India. PhD student Andhra University, Visakhapatnam, Andhra Pradesh, India 530 003, Phone # +919441184448, (email: viswanadhamch@bel.co.in) Professor, Department of ECE, Andhra University, Visakhapatnam, Andhra Pradesh, India 530 003, Phone # +91891 2531488, (email: pmraoauece@yahoo.com) 1
Fig. 1: Geometry of -plane sectoral horn Where, l Slant length of the horn, R0 Straight length of the horn, A Aperture, Flare angle, R Flare length and a Waveguide height 2.2 Field equations The derivations of E and field equations of -plane sectoral horn are given in [6]. These equations are extracted and shown at (1) and (2) for ready reference. 1cos sin 0.5 b.sin.sin FE () (1) 2 0.5 b.sin.sin 1 cos F( ). f (2) 2 Where A/2 2 2 x j R x 0 jxsin f ( ) cos e e dx A A/2 2.3 Directivity The directivity of -plane sectoral horn antennas is calculated using following procedure [6-7, 9]. Step-1: Calculation of X using the formula A 50 X (3) l Step-2: Using this value of X, we have calculated G value from Fig. 2, since X > 2. Otherwise we need to calculate G using formula 32 G X (4) X Fig. 2: G as a function of X ence G = 70. Step-3: Now we have calculated D using the formula b G D (5a) 50 l And in db= 10log( D ) (5b) 2.4 V.S.W.R The V.S.W.R of the waveguide fed horn element is given [7] by ( z ) ir 1 i ( ) 0, R Z z, ln( i Z e zi ) (6) n Rh Z0 Where z i the impedance of each section of the horn and n is the total number of sections of the horn. 2.5 Array The array gain with N elements is given [5, 14] by GArray Gelement 10log( N) (7) III DESIGN CALCULATIONS & SIMULATIONS 3.1 Specifications of Array The specifications of linear array of - plane sectoral horns with 8 elements are given at Table-1. TABLE-1 DESIGN SPECIFICATIONS OF ARRAY Sl. No. Parameter Linear array of - plane sectoral horns 1. Frequency range 6-18 Gz 2. No of elements 8 3. V.S.W.R Max. 2.5:1 4. (Min.) 15.8 dbi 5. 3-dB beam width (Az & El) 5-20 6. Power handling of 100 Watts CW element 2
3.2 Design Calculations of the element Based on the above requirements, the design parameters of -plane sectoral horn element at 6 Gz are calculated and given at Table-2. The simulation and measurement of V.S.W.R of the -plane sectoral horn element is beyond the scope of this paper. The improvements of the array in V.S.W.R by 0.3 (from 3.0 to 2.7) and gain by 0.44 db (from 14.04 to 14.48 dbi) is demonstrated with hybrid tapering [9]. These parameters need further improvement to achieve targeted V.S.W.R of 2.5:1 and gain of 15.8 dbi without changes in the dimensions of the element (Table-2), as the array is required for air-borne applications. Thus a new technique, tuning post loading on aperture is proposed in this paper. TABLE-2 DESIGN CALCULATIONS OF TE ELEMENT D (dbi) D G X A 6.5 4.2 70 7.3 136. 4 R 0 344.6 l 351.3 3.3 Simulation of Array The arrangement of the array of -plane sectoral horns is shown at Fig. 3. Length of the array = 78.8, N=8 10.5 Fig. 3: Arrangement of elements of linear array of -plane sectoral horns 37.5 The elements of the array are arranged syetrically on both sides of the center line without loss of generality to meet the spacing requirement of the elements of the array (i.e. 25 which is < λ/2 @ 6 Gz) to avoid grating lobes. The simulated model consists of hybrid tapering, aperture smoothening [9, 11] and tuning post loading on aperture. The Solid model diagrams of the simulations are shown at Fig. 4. A pair of brass tuning posts of 1.4 diameter with λ/2 apart at the center on the aperture have created a large wave front and exhibited improvement in matching impedance of the waveguide impedance ( Z ) g at low frequencies near S.M.A port. The location and the separation distance between these posts on the aperture are optimized in simulation. Also, the aperture area and thus gain of the array is increased due to hybrid tapering. Fig. 4: Simulated Model hybrid tapering, aperture smoothening and tuning post loading on aperture of linear array of -plane sectoral horns The simulated V.S.W.R for 5 th element of the array is shown at Fig. 5. The V.S.W.R data for single post at center, dual posts at center and dual posts at center with λ/2 separation is plotted. The V.S.W.R in 98% of the band is within 2.5:1 when dual tuning posts loading at center with 25 separation is simulated. The simulation of radiation pattern and gain is carried out at all frequencies from 6 to 18 Gz at 1 Gz step and the radiation patterns in azimuth and elevation plane of port 5 of 8 element array at 6 Gz and 18 Gz are shown at Fig. 6 to Fig. 9 respectively. The peak gain in simulation for azimuth pattern at port 5 is 15.45 dbi and 21.46 dbi at 6 Gz and 18 Gz respectively. 10 8 6 4 2 1 V.S.W.R Aperture smoothening and hybrid tapering Tuning posts positioned at aperture --- Single post at center --- Dual posts with separation --- Dual tuning post with λ/2 separation 6 8 10 12 14 16 18 Frequency in Gz Fig. 5: Simulated V.S.W.R with ybrid tapering, aperture smoothening and tuning 3
post loading on aperture of linear array of - plane sectoral horns Fig. 6 Azimuth radiation pattern at 6 Gz Fig. 9 Elevation radiation pattern at 18 Gz ybrid taper and aperture smoothened elements Tuning posts at 25 separation Fig. 7 Elevation radiation pattern at 6 Gz IV. PROTOTYPE FABRICATION & RESULTS The antenna array with eight elements is manufactured, out of which four elements are fabricated with hybrid tapering, aperture smoothening and the array is loaded with dual tuning posts on aperture with separation of 25 (corresponding to / 2 at 6 Gz) between them. Additional two similar plates (spares) are manufactured and attached to the sides of the array to address the mounting issues, which are used as duy plates in the array. The pictures of the prototype model are shown at Fig. 10. Fig. 10: Prototype of linear array of eight - plane sectoral horns V. EXPERIMENTAL RESULTS The measured V.S.W.R for 5 th element is shown at Fig. 11. The maximum V.S.W.R obtained is 2.45. The array has exhibited similar results for V.S.W.R for all other seven ports. The radiation pattern is measured from 6 to 18 Gz with 1 Gz step when excited with Rotman lens network and the radiation pattern in azimuth and elevation planes at 6 Gz and 18 Gz for 5th element is shown at Fig. 12 and Fig. 13. The radiation patterns of all ports from 6 to 18 Gz are not presented here, but in agreement with simulated results. The measured gain for 5 th port of the array for Azimuth Plane (A.P.) and Elevation Plane (E.P) is tabulated at Table-3. The radiation patterns at Fig. 6 to Fig. 9 are compared with that of Fig. 12 to 13. The measured V.SW.R and gain are meeting the specifications given at Table-1. Fig. 8 Azimuth radiation pattern at 18 Gz 4
measured results are presented in the paper for comparison. It is concluded that the simulated and measured results are in agreement. Fig. 11 Measured V.S.W.R plot of 5 th element in the 8 element array Fig.12. Measured radiation pattern of 5 th element of linear array of -plane sectoral horns at 6 Gz, Azimuth and Elevation planes Fig.13. Measured radiation pattern of 5 th element of linear array of -plane sectoral horns at 18 Gz, Azimuth and Elevation planes VI. CONCLUSION ----- Azimuth ----- Elevation ----- Azimuth ----- Elevation A linear array with eight sectoral horn elements using hybrid taper, aperture smoothening and tuning post loading is simulated, manufactured and tested for V.S.W.R and. The radiation patterns at 6 Gz and 18 Gz for both simulation and TABLE-3 SIMULATED & MEASURED GAIN WIT TUNING POST LOADING S. No. Freq. in Gz simulated in dbi in. A.P. measured in dbi in A.P. simulated in dbi in. E.P. measured in dbi in E.P. 1. 6.0 15.45 15.62 15.35 15.52 2. 18.0 21.46 21.98 21.36 21.29 ACKNOWLEDGEMENT The authors are thankful to the engineers working at BEL for sparing their valuable time during the simulation and measurements. We also extend our sincere thanks to management of B.E.L for providing all the facilities like Simulation tools, igh end work stations, Compact Antenna Test Range (C.A.T.R), Vector Network Analyzer, etc., during the work. We sincerely extend our gratitude to Prof. P Rajesh Kumar, OD, ECE department, Andhra University, yderabad for his support during the preparation of the paper. REFERENCES [1] ans Schantz, Antenna as Transducers and Antennas as transformer, in the title of Art and Science of Ultra Wide Band antennas 1 st edition, 2005, Artech publications [2] Pues.F, An impedance-matching techniques for increasing the bandwidth of micro strip antennas, Antennas and Propagation, IEEE transactions Vol. 37, issue 11, pages 1345-1354, ISSN: 0018-926X, 06 Aug 2002. [3] Constantine A Balanis, Antenna Theory Analysis and design with multimedia CD, 3 rd edition, Wiley India, reprint 2012. [4] Ronaldo O. dos Santos and Carlos Leonidas da S. S. Sobrinho, FDTD method: Analysis of an one-dimensional array of - plane sectoral horn antennas with dielectric lens, Revista Científica Periódica, Telecomunicações, Telecomunicações, Vol. 06, No.1, pp. 28-32, June 2003 [5] Tae-Young Kim, Young-Min Yoon, Gun- Su Kim, and Boo-Gyoun Kim, A Linear Phased Array Antenna Composed of Inductive 5
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